Evidence for alkali metal induced intermolecular acetylenic hydrogen

J . Phys. Chem. 1985, 89, 4094-4098

4094

Evidence for Alkali Metal Induced Intermolecular Acetylenic Hydrogen Atom Transfer between Hydrogen-Bonded Alkyne Complexes in Solid Argon Laurent Manceron and Lester Andrews* Chemistry Department, University of Virginia, Charlottesville, Virginia 22901 (Received: July 24, 1984;

In Final Form: April 8, 1985) Condensation of acetylene, propyne, and 2-butyne/acetylene mixtures with heavy alkali metal atoms (Na, K, Cs) in an argon matrix at 15 K has led to the appearance of infrared absorptions due to ethylene, propylene, and trans-2-butene, respectively. These results stand in sharp contrast with the products obtained with lithium. Isotopic studies have shown that ethylene formation involved three different acetylene molecules and evidenced a difference in the product yield with hydrogen vs. deuterium as well as a preference for trans- vs. cis-C2H2D2formation, which is discussed and rationalized by differences in the zero point energies for the different mixed deuterium isotopes of the intermediate vinyl radical. This trend is amplified by methyl substitution. Spectroscopic evidence was found in these experiments for cesium acetylide (Cs+C2H-) and a cesium-acetylene a complex, which are involved in the intermolecular acetylenic hydrogen atom transfer process.

Introduction In recent years, the important use of organoalkali compounds as catalysts for polymerization of olefins, as well as their increasing use as reagents in organic synthesis or intermediates for the preparation of various kinds of organometallic compounds,' has stimulated a great deal of theoretical and experimental research. At the macroscopic scale, direct action of alkali metals on unsaturated hydrocarbons has been used for addition to carboncarbon double bonds,2 for metal/hydrogen exchange if the corresponding carbanion has evidenced some ~ t a b i l i t y for , ~ metal/ halogen exchange in all cases,and finally for a hydrogenation agent using liquid ammonia as reaction medium and hydrogen source." Metal atom cryochemistry, where metal atoms are condensed with reactants in a large argon excess to isolate the reaction intermediate, has beed widely used to study complexation of various a systems (acetylene, ethylene, propylene, benzene) by transition-metal atoms.5 Interaction of alkali metals with acetylene at a microscopic scale, without solvent effects or influence of the reaction medium, presents an interesting problem as it could proceed through weak complexation or radical formation as an alternative to the rather unfavorable charge transfer (EA = -1.8 eV).6 A matrix ESR study has reported reactions of Na atoms with acetylene, and characterized charge-transfer species, the mast stable one identified as vinylidene radical anion, and has observed the vinyl radical in concentrated samples of acetylene.' In a previous paper, we have described the results of a study of the lithium and acetylene matrix system, which gave LiC2H2 and Li2CzH2molecules where lithium symmetrically bridges the A system, perturbs the C2H2group, and bends it away from linearity.* We present here an infrared study of the reaction products obtained by codeposition of heavy alkali metal (Na, K, or Cs) with acetylene, propyne, and 2-butyne molecules diluted in solid argon.

Experimental Section The cryogenic refrigeration system, vacuum vessel, alkali metal source, and experimental techniques have been described earlier.g (1) "Handbook of Organometallic Compounds", N. Hagihara, M. Kumada, and R. Okawara, Ed., W. A. Benjamin, New York, 1968. (2) (a) J. A. Momson, C. Chung, and R. J. Lagow, J . Am. Chem. SOC. 97,5015 (1975); (b) L. A. Shimp, C. Chung, and R. J. Lagow, Inorg. Chim. Acta, 29, 7 1 (1978). (3) R. Nast and J. Gremm, Z . Anorg. Allg. Chem., 325, 62 (1963). (4) A. Farkas and L. Farkas, Trans. Faraday SOC.,33, 337 (1937). (5) (a) H. Huber, G. A. Ozin, and W. J. Power, J . Am. Chem. SOC.,98, 6509 (1976); (b) G. A. Ozin, D.McIntosh, W. J. Power, and R. P. Messmer, Inorg. Chem., 20, 1782 (1981); (c) P.Kasai, J. Am. Chem. SOC.,105, 6704 (1983); (d) J. H. B. Chenier, J. A. Howard, B. Mile, and R.Sutcliffe, J . Am. Chem. SOC.,105, 788 (1983); (e) J. A. Howard, R. Sutcliffe, 3. S. Tse, and B. Mile, Organometallics, 3, 859 (1984). (6) S. Y.Chu, L. Goodman, and R. Okawana, J . Am. Chem. SOC.,97,7 (1 975).

(7) P. Kasai, J . Phys. Chem., 86, 4092 (1982). (8) L. Manceron and L. Andrews, J . Am. Chem. SOC.,107, 563 (1985).

0022-3654/85/2089-4094$01.50/0

Sodium and potassium metal (Baker and Adamson, 99.9%) were vaporized directly from the liquid phase, whereas an atomic beam of cesium was generated by reaction of molten lithium metal (Fisher) and cesium chloride (Fisher) in a Knudsen cell maintained at 300 OC.Io High-purity acetylene (Matheson) and argon (Air Products, 99.995%), I3C2H2,and C2Dz(MSD Isotopes) were used without further purification. 2-Butyne (provided by R. N. Grimes) and propyne (Matheson) were frozen, thawed, and outgassed at liquid nitrogen temperature before use. In each experiment, 40 mmol of gaseous argon and the reactant mixture were injected in about 18 h. The mixture was condensed on a cold CsI window (- 15 K) simultaneously with the metallic vapor effusing from the Knudsen cell. In order to estimate the yield of product in the experiment, the total amount of matrix was derived trapped on the deposition window (0.75 f 0.05 "01) from the interference fringe patterns recorded on the spectrum after deposition. This value was checked by measuring band areas of the two IR-active bands of the precursor (vj and v5) in blank experiments and deriving the amount of acetylene trapped from the integrated absorptions measured by previous workers. Assuming an equal trapping rate for argon and acetylene, one obtains 0.7 f 0.1 mmol of matrix deposited, in agreement with the previous result. Similar measurements were also carried out with blank samples of C2H4 and CZD4. Infrared spectra were recorded with a Beckman IR-12 and a Perker-Elmer 983 spectrometer with data station. The spectra presented here were processed against a background collected with the bare CsI window and then base-line corrected to compensate for matrix scattering. Frequency accuracy is better than f0.5 cm-' with slidwidths of 1 cm-' in the product band regions.

Results Alkali metal matrix reactions will be described for three alkyne systems. Acetylene and Alkali Metals. Several experiments were run depositing sodium, potassium, and cesium atoms with different acetylene/argon mixtures in order to determine the best reaction conditions. In all the experiments there arose only two sets of new absorptions. The first set (marked C in Figure 1) is characterized by broad absorptions slightly shifted from the position of the different fundamentals of acetylene, whereas the other set (marked by arrows) shows sharp lines completely separated from parent molecule absorptions. Although no frequency shift was detected (within measurement accuracy) for these new product bands with the different alkali metals, a 2-3-fold increase in product yield was observed when going from sodium to cesium (9) L. Andrews, J. Chem. Phys., 48, 972 (1968). (IO) L. Andrews, J.-T. Hwang, and C. Trindle, J. Phys. Chem., 77, 1065 (1973). (1 1) D. F. Eggers, I. C. Hisatsune, and L. van Alten, J . Chem. Phys., 59, 1125 (1955).

0 1985 American Chemical Society

The Journal of Physical Chemistry, Vol. 89, No. 19, 1985 4095

H-Bonded Alkyne Complexes in Solid Ar

Figure 1. Infrared spectra recorded after condensation of 0.75 f 0.05 mmol of argon/acetylene = 200/1 mixture at 15 K for 18 h: (a) C2H2+ cesium atoms; (b) C2H2without cesium atoms; (c) C2D2with cesium atoms; (d) C2D2without cesium atoms. A designates acetylene fundamentals or combination bands of the different isotopic species of acetylene; W and Ac designate water and acetone absorptions present as impurities. The bold arrows indicate C2H4 product bands, and open arrows denote absorptions due to C2D4product. TABLE I: Gas-Phase and Matrix Fundamentals ( u , cm-l) for Ethylene and Deuterium-SubstitutedIsotopes

u

matrixb A

u

A

y4

u,

949.2

81.8

947

115

Ya ~ 1 2

1443.5

t-C H D gasC matrixbsd

C2H3D

C2H4

gas"

9.8

1440

19.5

u

U

u

A

Y

1000

1003 807

988 727

37.0 24.8

992 725

809 943 1404

1399

1300

7.7

u 843

1298

1344

"R. Golike, I. Mills, W. Person, and B. L. Crawford, Jr., J. Chem. Phys., 25, Reference 14. Reference 13.

for similar experimental conditions. Figure 1 presents spectra recorded for reaction of Cs atoms with normal and deuterated acetylene, contrasted with blank sample spectra. With normal acetylene the most prominent product is characterized by two bands at 1440 and 947.2 cm-' (with a broad shoulder at 960 cm-I). These bands shift to 1074 and 724 cm-' with the deuterated precursor and other weak signals given ih Table I appear, whose relative intensities vary with the amount of C2H2and CzHD traces in the experiments. The observation of the mixed H / D counterparts of the product at 1440 and 947 cm-l requires careful comparison with blank spectra, for two of these bands overlap some of the parent molecule (v4 v5 combination of CzD2and v5 of C2H2present in traces in the CzD2 sample). Figure 2 illustrates the relative intensity changes in the 1399-, 1305-, 1295, 1003-, 991-, 922-, 847-, and 764-cm-' bands with different C2H,/C2D2ratios. These changes allow separation of the latter bands into several groups, which will be assigned to C2H,D, species (x y = 4), as given in Table I. Irradiation has been camed out with medium- and high-pressure mercury arcs without any noticeable change in the entire spectrum; likewise annealing does not further affect the sharp bands but increases the broad 960-cin-' band. Careful comparison with blank experiments run without metal also evidences weak new features at 3345, 3240, 1960, and 632

+

+

c-C~H~D~ C2HD3 gasc matrixb A 71.9 6.9

U

847 1335

U

Y

764 723 918 1290

765

1267 (1956); A (km mol-')

922 1305

C2D4

gas'

matrixb

u

A

u

720

41.8

722

1078

5.2

1073

A 88 10.8

is the extinction coefficient. bThis work.

cm-' (labeled C in Figure 1) as listed in Table 11. The two signals at 1960 and 632 cm-' overlap weakly activated v2 and v4 acetylene fundamentals in the dimer and polymers at 1971 and 621 c ~ - ~ , ~ ~ J ~ but are one order of magnitude more intense. The signal at about 3240 cm-' forms a shoulder on the low-frequency side of the 3265-cm-' v3 band of the hydrogen-bonded CzH2dimer reported by previous workers.I2 Finally, other weak absorptions ( A = absorbance = 0.02) at 1856 (labeled D), 2978, 2890, and 1265 cm-' are seen in the most concentrated cesium experiments, and these bands grow on annealing the matrix. Propyne and Cesium. When cesium atoms were codeposited with propyne, extra absorptions at 1649, 1452, 997, 909.5, and 582 cm-' were produced, along with a weak feature at 2124 cm-l shouldering the 2135-cm-' v(C=C) mdde of propyne. 2-Butyne and Acetylene and Cesium. Figure 3 shows the result of addition of cesium atoms to an acetylene/2-butyne (DMA) mixture. In addition to the C features and the 947-cm-' absorption already observed in experiments with acetylene as the only hydrocarbon reagent, a sharp absorption was observed at 976.2 cm-I, which shifted to 755 cm-' when deuterated acetylene was used. A broad, weak feature also appeared at 1890 cm-' between the (12) N. Baganskis and M. Bulanin, Opr. Specfrosc., 29, 687 (1970); 35, 525 (1972).

4096

The Journal of Physical Chemistry, Vol. 89, No. 19, 1985

Manceron and Andrews

TABLE II: New Absorptions (em-') Produced by Codeposition of Alkali Metal Atoms (Na,K, Cs) and Acetylne in Solid Argon, Compared to Fundamentals of Acetylene in the Cas Phase mode C2H2" M + C2H2 C2D2" M C2D2 product label ZJvl)v,CH 3374 3345 2701 2680 C WdvaCH 3295 (3300)b -3240 2439 (2442)b -2410 C 3283 (3285)b qy2)% 1974 (P,1971)d 1 96OC 1762 (P,1760) 1749 C 1856 1735 D 730 (737)b 537 (544)b IIU(V5)WCH qV4)WCH 612 (P. 620) 632 505 (P,512) 515 C

*

"Gas-phase data, ref 17. bMatrix data; this work. CThe "C2H2 counterpart was 1898 cm-'. d P = polymers.

-D

C2H3D

--(.trans

-

(observed as an impurity in a C2D4blank sample), whereas the bands at 847 cm-', on the one hand, and 991 and 1298 cm-', on the other hand, correspond to the positions of the strongest absorptions of cis- and trans-CzHzDz in an argon matrix.13 The other reported strong absorptions at 725 and 1335 cm-' would be overlapped by u5 and u4 v5 of C2H2. The remaining species absorbs at 1399, 1003, and 807 cm-',close enough to the positions of vl2,u4, and v7 of C2H3D(reported at 1404, 1O00, and 809 cm-' in the gas phase)14 to confirm the identification of C2H3D. Therefore all the different mixed H, D isotopes of ethylene (except CH2CD2)were observed as reaction products of C2H2 C2Dz in presence of alkali atoms. A fact immediately obvious from the appearance of C2HD3and C2H3D reaction products in the CzD2 sample (96% C2D2, 4% C2HD) is that the process must involve three different acetylene molecules, since C2HDis only present as an impurity. It is possible to estimate the amount of ethylene formed in the different experiments by band area measurement and comparison with integrated absorption gas-phase data, or matrix isolated C2H4 and C2D4. In two successive experiments run with C2H2and C2D2 in similar experimental conditions, 0.95 f 0.1 pmol of C2H4 was formed in the first case while the amount of C2D4 detected in the second case was 0.7 f 0.1 pmol. Two observations are also very striking when comparing the distribution of the different deuterium isotopes. For instance, in the experiment presented in Figure 2c, only traces of C2H2and a small amount of C2HD (4%) were present: (i) A noticeable decrease in product yield with deuteration pmol of C2H4and 17.4 X and 4.7 X occurred: 8 X Nmol of respectively trans- and cis-C2H2D2were formed, compared with the C2D4amount cited above. These data give a C2H4/ C2HZD2/C2D4= 1/2.8/8.8 ratio instead of the 1/650/49O00 ratio obtained from a purely statistical model with identical H / D reaction rates. The lack of knowledge of the C2H3Dand C2D3H extinction coefficient does not allow further quantitative comparison of the C2D2vs. the C2Ht!eaction rate, but relative band intensities support this trend. (11) There exists roughly a 3.4/1 ratio for the trans- and cis-C2H2D2product formed, which indicates that, in the process of addition of a first hydrogen atom to a CzD2or C2H2precursor, the trans intermediate is favored. The product observed with propyne can be identified by following the above alkali metal induced alkyne hydrogen transfer to the alkyne triple bond: the five observed product bands match (within 1 cm-')the five strongest absorptions of propylene.ls The main product observed with 2-butyne is formed in presence of acetylene and is characterized by one sharp absorption at 976.2 cm-' (755 cm-l with C2D2,H / D ratio 1.293), which is coincident with the strongest line of trans-2-butene (H-C=C-H out-of-plane d e f ~ r m a t i o n ) 'whose ~ other strong absorption (methyl group deformation) would not be shifted enough from parent butyne bands to be observed here. Fortunately, however, the spectrum shows unambiguously that no band is present at 680-685 cm-' where cis-2-butene, the other possible isomer, would have its strongest absorption,I6 thereby indicating that methyl group

+

+

i

I

,

,

1400

,

,

,

I

1200

,

I

,

I

1000

I

I

d o

SAO

+

cm-1

Figure 2. Expanded scale infrared spectra of the CCH bending region for different argon/acetylene (C2H2 C2D2)= 200/1 mixtures with and without cesium atoms in an argon matrix: (a) C2H2/C2HD/C2D2= 1/0/0, solid line is with Cs atoms, dotted line is without Cs atoms; (b) C2H2/C2HD/C2D2= 0.33/0.04/0.63with Cs atoms; (c) C2H2/ solid line is with Cs atoms, dotted line C2HD/C2D2= 0.005/0.055/0.94, is without Cs atoms. A designates acetylene fundamentals or combination bands of the different isotopic species, and Ac designates acetone impurity absorptions.

+

C and D species absorptions, but it does not shift upon deuteration. None of these features was observed in a cesium experiment with 2-butyne and no acetylene.

Discussion The new products of the matrix reaction of alkynes with heavy alkali metal atoms will be identified and reactions occurring in the matrix will be considered. Identification. The complexity of the pattern observed in isotopic mixtures shows unambiguously that the main reaction product contains more than two hydrogen atoms; moreover, the coincidence of the position and relative intensity of the two product bands with the two strongest v7 and vI2 bands of ethylene observed at 947 and 1440 cm-'(Z947/11440 = 5 ) with C2H4 and 722 and 1073 cm-' (1722/11073 = 9) with C2D4 in solid argon is striking. In the isotopic mixture experiments, the signals observed at 764.5,922, and 1305 cm-I match exactly the strongest C2HD3absorptions

(13) M.E. Jacox, personal communication. (14)B. L. Crawford, Jr., J. E. Lancaster, and R. G. Inskeep, J . Chem. Phys., 21, 678 (1953). (1 5) L. Andrews, G.L. Johnson, and B. J. Kelsall, J . Am. Chem. Soc., 104, 6183 (1982). (16)A. J. Barnes and J. D. Howells, J . Chem. Soc., Faraday Trans. 2.69, 532 (1973).

The Journal of Physical Chemistry, Vol. 89, No. 19, 1985 4097

H-Bonded Alkyne Complexes in Solid Ar

C

3000

2000

1500

500

1000

cm-1

Figure 3. Infrared spectra recorded after deposition of 0.75 mmol of argon/2-butyne (DMA)/acetylene = 200/0.5/1 mixture at 15 K for 18 h: (a) with cesium atoms; (b) without cesium atoms. A designates acetylene fundamentals or combination bands and DMA the fundamentals of 2-butyne, W and Ac water and acetone impurity absorptions. The bold arrow indicates the C2H4product band already observed with acetylene as the only reagent, and the black-headed arrow denotes the new product observed with the addition of 2-butyne.

substitution of acetylenic hydrogen favors even more a trans hydrogenation. The broad bands labeled C in Figure 1 are only slightly shifted from acetylene absorptions with no noticeable difference for Na, K, and Cs, and no new features wereobserved for CzH2/C2Dz mixtures. The C bands are present in dilute acetylene experiments and are thus likely to belong to a species containing one acetylene molecule. An important fact is that the absorption observed at 1960 cm-] shifts upon deuteration to 1749 cm-I, the same amount as acetylene (v(C=C), 1974 to 1762 cm-' in the gas phase);I7 therefore, this species contains two hydrogen atoms, the 200-cm-' deuterium shift indicating a similar v ( ~ ) / v s y m ( C - H ) coupling as in acetylene itself. (In the ethynyl radical (HC,) only a 100-cm-' shift was observed for the C z C stretching mode on deuteration.)]* For these reasons, the C bands are assigned to a weak alkali metal/acetylene van der Waals 7 complex of CZa symmetry with the vl, v2, and v4 modes activated,17 although we cannot completely exclude the possibility that alkali metal atoms could induce enough asymmetry in the argon lattice to create such a perturbation of C2H2molecules. The band labeled D at 1856 cm-1 with C2H, is produced on reagent deposition and it grows markedly upon annealing along with the broad 960-cm-I absorption. The latter band is due to a more perturbed ethylene formed in acetylene aggregates by cesium atom diffusion. In the deuterated acetylene experiments, the only counterpart which could be found for the 1856-cm-I band is the broad 1735-cm-l shoulder on the C complex absorption. The relative magnitude of the deuterium shift as well as a cornparison with previous data obtained for alkali metal acetylide salts (1825-1 860 cm-1)3 suggests assignment of this signal to the c e stretching mode of the acetylide anion in the Cs+C2H- ion pair; however, the failure to observe the methyl-substituted counterpart with propyne precludes a definite assignment, although the (17) W. J. Lafferty and R. Thibault, J . Mol. Specfrosc., 16, 15 (1965); J. F. Scott and K. Rao, ibid., 20, 438 (1966). (18) M. E. Jacox, Chem. Phys., 7, 424 (1975).

SCHEME I

M

+

T

-:c liq

I R

M+

/"I

7'

'C

I/

+

/".

R

11 +

M+NH,-

?\

R

+NH; +M

H H

R'

\C/

/I +

2(M+NH2-)

/"\H

R

m ~ h a n i s mto be described below requires the Cs'CzH- species. The band observed at 1890 cm-' with 2-butyne, cesium, and acetylene does not show any acetylene deuterium shift and Cannot be assigned in this work. Reactions Occurring in the Matrix. Alkali metal induced hydrogenation of alkynes has been observed in liquid ammonia4 where the proposed mechanism first involved metal atom valence electron transfer and then proton transfer from ammonia in two steps (Scheme 1). The trans addition is favored because the ~r&m~ediateradical anion is supposed to Prefer a trans configuration. In an ESR matrix isolation study of the Na/C2H, interaction, Kasai reported evidence for three charge-transfer species differing by their photoactivation energies? None of them can be identified here, although multiple irradiations were performed. Interaction between metal and the very weakly perturbed acetylene group of complex c Seems very unlikely to involve charge transfer. However, at higher acetylene concentration, Kasai observed the vinyl radical, the intermediate in the formation of ethylene, the latter Of which was produced in this work' Kasai suggested that hydrogen bonding plays a key role in the process of hydrogenation for vinyl radical formation, which has already been proposed from

4098

The Journal of Physical Chemistry, Vol. 89, No. 19, 1985

gas-phase kinetic data where a 3/ 1 HCl/propylene ratio was found necessary for hydrogen chloride addition to pr0py1ene.I~ This proposal is also supported by the fact that heavy alkali metal codeposited with ethylene in similar infrared experiments gives no evidence for reaction product;20it is well-known that acetylenic C-H bonds exhibit acidic character and therefore undergo stable hydrogen bonding'2v21,22as opposed to weak van der Waals interaction loosely bonding the ethylene dimer.23s24Therefore, vinyl radicals are generated by addition of one alkali metal atom to an acetylene dimer, as suggested by Kasai, then further encounter with another metal-acetylene van der Waals pair will lead to formation of ethylene and a second metal acetylide (Scheme 11). The latter is probably species D absorbing at 1856 cm-' (1735 with C2Dz),which is obviously a much weaker infrared absorber. The sharpness of the ethylene product bands, the lack of frequency shift when going from Na to Cs, and agreement with matrixisolated ethylene15 might indicate that this product is formed at the liquidsolid interface during the growth of the matrix sample and then surrounded by argon atoms, while the 960-cm-' broad absorption might correspond to more perturbed ethylene formed by reaction of two metal atoms and the acetylene trimer in the matrix. Similar lithium-acetylene experiments gave a bridged LiC2H2 species and no evidence for ethylene.* The higher ionization energy of lithium and its ability to form a strong T complex make formation of the charge-transfer intermediate leading to the acetylide more difficult, and the latter species is required for intermolecular H-atom transfer. It is also interesting to consider the preference experimentally shown for trans-dideuterioethylene and trans-2-butene. In a complete theoretical investigation of the H + CzH2 C,H, reaction, Harding et al. have computed an equilibrium geometry for the vinyl radical, and harmonic frequencies and zero point energies for the different deuterium isotopes.25 If we compare their results for the four different mixed hydrogen-deuterium isomers

-

D

H

\,c=c.

/D

6 zpe=20.31 kcall mol D

\

/D

F=C* ri

z pe = 20.46 kcal/ mol ti

6 zpe =22.27 kcal/mol

zpe=22.14 kcal/mol

one sees that the zero point energies favor the trans form by 0.15 kcal/mol (-52 cm-') for addition of H atoms to a C2Dzprecursor, (19) M. Haugh and R. Dalton, J . Am. Chem. SOC.,97, 5674 (1975). (20) L. Manceron and L. Andrews, unpublished results. (21) A. Engdahl and B. Nelander, Chem. Phys. Lett., 100, 129 (1983). (22) R. E. Miller, P. F. Vohralik, and R. 0. Watts, J . Chem. Phys., 80, 5453 (1984). (23) E. Rytter and D. Gruen, Spectrochim. Acta, Part A, 35A,199 (1979). (24) D. R. Cowieson, A. J. Barnes, and W. J. Orville-Thomas. J . Raman Spectrosc., 10, 224 (1981). ( 2 5 ) L. Harding, A. Wagner, J. Bowman, G . Schatz, and K. Christoffel, J . Phys. Chem., 86, 4312 (1982).

Manceron and Andrews SCHEME I1 H-CFC-H

,

I

H

II

M-

4

-

H-CEC-H

/" rtl

C

C

H

H

I

7 7 - /"="

+M CZHZ

+

H

M+ - C E C - H

I

H

\ ? /"=7

H

H

but the cis form by 0.13 kcal/mol (-45 cm-') for addition of D atoms to a C2H2precursor. Assuming a 50 K temperature (above which proper isolation is no longer experimentally possible with argon) one obtains an overall 2.8/ 1 trafis/cis Boltzmann population ratio close to the 3.4/1 experimentally observed. Of course a kinetic isotope effect, impossible to estimate from the data but a plausible explanation for the C2D4/C2H4yield discrepancy, would lower the temperature required to obtain the observed trans/& ratio. Furthermore, the 8 kcal/mol inversion barrierz6 for the vinyl radical would, of course, forbid cis-trans interconversion at these temperatures. Substitution of hydrogens by two methyl groups seem to favor even more in trans hydrogen addition product. Conclusions

Codeposition of heavy alkali metal atoms (Na, K, and Cs) with acetylene and methyl-substituted acetylenes in an argon matrix gives evidence for alkali metal induced intermolecular acetylenic hydrogen transfer to the C=C triple bond to form ethylene. Spectroscopic evidence was obtained for a weak cesium-atomacetylene ?r complex and cesium acetylide, which are involved in the intermolecular hydrogen atom transfer mechanism. These results are substantially different from the product of similar lithium studies and provide support for the role of hydrogen-bonded intermediates prior to hydrogen atom transfer. The addition also shows a preference for hydrogen relative to deuterium transfer, and a trans isomer selectivity (partial with C2H2Dzand total with C2H2(CH3),), which is tentatively rationalized in term of differences in zero point energies for the vinyl radical intermediate structures. Acknowledgment. Acknowledgment is made to the donors of the Petroleum Research Fund, administered by the American Chemical Society, for support of this work and to M. E. Jacox for helpful discussion on isotopic C2H4 spectra. Registry No. Na, 7440-23-5; K, 7440-09-7; Cs, 7440-46-2; D,, 7782-39-0; C,H,, 74-85-1; C,H,D, 2680-00-4; t-C,H,D,, 1517-53-9; c-C2H2D2,28 13-62-9; C2HD3, 2680-01 -5; C2D,, 683-73-8; acetylene, 74-86-2; propyne, 74-99-7; 2-butyne, 503- 17-3: cesium acetylide, 30180-52-0 (26) M. Dupuis and J. J. Wendolowski,J . Chem. Phys., 80, 5696 (1984).